Selective seed layer patterning of PVD metal stacks by electrochemical screen printing for solar cell applications

Gensowski, Katharina; Kamp, Mathias; Efinger, Raphael; Mikolasch, Gabriele; Eckert, Jonas; Bechmann, Sebastian; Weber, Ralf; Bartsch, Jonas

doi:10.1002/pip.3206

Cited by 7 publications

(5 citation statements)

References 10 publications

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“…This process sequence should be suitable for realizing the metal grid on solar cells. Therefore in future studies, the thickness of these metal layers needs to be varied in order to show that the electrochemical dispensing process provides a significant advantage over the electrochemical screen printing process because it is able to etch deeper into a metal layer at a constant etched line width 21 . Figure 6.…”

Section: Discussionmentioning

confidence: 99%

Conductive Highly Filled Suspensions for an Electrochemical Dispensing Approach to Pattern Full-Area Thin Metal Layers by Physical Vapour Deposition

Gensowski

Tepner

Schweigert

et al. 2020

Sci Rep

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This paper presents a systematic approach for the development of highly filled suspensions used for an electrochemical dispensing approach. electrochemical dispensing is an alternative structuring process to locally pattern pVD full-area thin metal layers with the goal to create contacts on solar cells or circuit boards by anodic metal dissolution. Achieving a narrow patterned line width requires a dispensing paste with a high yield stress, a small particle size distribution and a good electrical conductivity. Therefore this work focuses on the formulation and characterization of dispensing pastes in terms of their rheological and electrical properties and their particle size distribution. Furthermore, the printing performance is evaluated in dispensing experiments. In this study, samples with a yield stress above 5000 Pa and an average particle size below 0.4 µm were produced, resulting in dispensed line widths below 100 µm with a high aspect ratio above 0.6. The lack of electrical conductivity was solved by adding KCl solution to the paste, which will add to the ionic conductivity of the NaNO 3 basis paste formulation. With this approach, printed line widths down to 115 µm and etched line widths below 90 µm at high aspect ratio were achieved on 50 nm aluminum layers.

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Section: Discussionmentioning

confidence: 99%

Conductive Highly Filled Suspensions for an Electrochemical Dispensing Approach to Pattern Full-Area Thin Metal Layers by Physical Vapour Deposition

Gensowski

Tepner

Schweigert

et al. 2020

Sci Rep

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“…A selective layer of aluminum was applied to the black surfaces by the physical vapor deposition technique, PVD (Selvakumar, 2012;Valleti, 2016;Gensowski, 2019). Two deposition times were used, 2 and 5 min, providing metallic layers that reflect infrared and transmit visible and UV, with thicknesses between 20 and 30 μm (Figure 4a).…”

Section: Methodology Hypothesismentioning

confidence: 99%

Copper Black Coatings for the Absorption of Solar Concentration With an APPJ SiO2 Super-Hydrophobic Protection

Bueno

Rojas²,

Hernández

et al. 2021

International Journal of Environmental Sustainability and Green Technologies

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Solar thermal energy can be captured on absorbent surfaces, but coatings tend to deteriorate, due to changes in hue, thermal shocks, or detachment of all layers. There is a great challenge in reducing the deterioration because of environmental factors such as corrosion, impact, and dust control, among others. The absorbent coatings interact with the incident solar radiation transforming it as heat energy, and selectivity allows a low emissivity. In this work, a three-layer system on copper is proposed. An anodized CuO or black copper layer as an absorbent with high absorptance is proposed. A protective layer was added to extend the lifetime of use while preserving the functional characteristics of the absorbent black layer by using SiO2 deposited by atmospheric pressure plasma jet (APPJ) using hexamethyldisiloxane. A selective layer of aluminum was deposited by physical vapor deposition (PVD). Thermal shocks were applied by concentrated solar power with a Fresnel lens to represent sudden temperature changes in the radiation absorbent when the weather changes.

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“…Besides, solution‐based processing methods such as spin‐coating, [ 36 ] inkjet printing, [ 37 ] and screen‐printing [ 38 ] are also performed in OLEDs fabrication. For OPVs, compared with the traditional fabrication methods such as thermal evaporation [ 39–41 ] and spin‐coating, [ 42,43 ] scalable solution methods such as inkjet printing, [ 44,45 ] screen printing, [ 46 ] and roll to roll coating [ 47 ] are more attractive due to their compatibility with the mass production. For PSCs, the perovskite layer can also be deposited with spin‐coating, gas‐solid reaction, [ 48 ] blade or bar coating, [ 49–51 ] slot‐die coating, [ 52,53 ] spray coating, [ 39 ] inkjet printing, [ 54 ] electrodeposition, [ 55 ] pressure processing deposition, [ 56 ] vacuum deposition, [ 57 ] chemical vapor deposition (CVD), [ 58 ] etc.…”

Section: Introductionmentioning

confidence: 99%

A Review on Encapsulation Technology from Organic Light Emitting Diodes to Organic and Perovskite Solar Cells

Lü

Yang

Meng

et al. 2021

Adv Funct Materials

129

128

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Organic light emitting diodes (OLEDs) employing organic thin‐film based emitters have attracted tremendous attention due to their widespread applications in lighting and as displays in mobile devices and televisions. The novel thin‐film photovoltaic techniques using organic or organic–inorganic hybrid materials such as organic photovoltaics (OPVs) and perovskite solar cells (PSCs) have become emerging competitive candidates with regard to the traditional photovoltaic techniques on account of high‐efficiency, low‐cost, and simple manufacturing processing properties. However, OLEDs, OPVs, and PSCs are vulnerable to the undesired degradation induced by moisture and oxygen. To afford long‐term stability, a robust encapsulation technique by employing materials and structures that possess high barrier performance against oxygen and moisture must be explored and employed to protect these devices. Herein, the recent progress on specific encapsulation materials and techniques for three types of devices on the basis of fundamental understanding of device stability is reviewed. First, their degradation mechanisms, as well as, influencing factors are discussed. Then, the encapsulation technologies and materials are classified and discussed. Moreover, the advantages and disadvantages of various encapsulation technologies and materials coupled with their encapsulation applications in different devices are compared. Finally, the ongoing challenges and future perspectives of encapsulation frontier are provided.

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Selective seed layer patterning of PVD metal stacks by electrochemical screen printing for solar cell applications

Cited by 7 publications

References 10 publications

Conductive Highly Filled Suspensions for an Electrochemical Dispensing Approach to Pattern Full-Area Thin Metal Layers by Physical Vapour Deposition

Conductive Highly Filled Suspensions for an Electrochemical Dispensing Approach to Pattern Full-Area Thin Metal Layers by Physical Vapour Deposition

Copper Black Coatings for the Absorption of Solar Concentration With an APPJ SiO2 Super-Hydrophobic Protection

A Review on Encapsulation Technology from Organic Light Emitting Diodes to Organic and Perovskite Solar Cells

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